128 Crop Breeding and Applied Biotechnology 14: 128-131, 2014 JS Lira Júnior et al.
UFV-M7: mutant yellow passionfruit genotype with photoperiod
insensitivity for lowering
José Severino de Lira Júnior1*, Patrícia Silva Flores2 and Cláudio Horst Bruckner3
Received 19 March 2013 Accepted 26 November 2013
Abstract – The development and characteristics of UFV-M7, a mutant with photoperiod insensitivity to beginning of lowering, are described. This genotype was fortuitously obtained by regeneration of nodal segments, exposed to gamma radiation. The possibil-ity of incorporating photoperiod insensitivpossibil-ity into cultivars for producing regions is discussed for latitudes where the photoperiod determines the seasonality of harvest.
Key words: Passilora edulis, mutation, lowering, photoperiod.
Crop Breeding and Applied Biotechnology 14: 128-131 2014 Brazilian Society of Plant Breeding. Printed in Brazil
CULTIVAR RELEASE
http://dx.doi.org/10.1590/1984-70332014v14n2c22
1 Instituto Agronômico de Pernambuco (IPA), Avenida General San Martin, 1371, Bongi, 50.761-000, Recife, PE, Brazil. *E-mail: lira.junior@ipa.br 2 Embrapa Acre, Rodovia BR-364, km 14, C P 321, 69.900-056, Rio Branco, AC, Brazil
3 Universidade Federal de Viçosa (UFV), Departamento de Fitotecnia, Avenida Peter Henry Rolphs, s/n, Campus Universitário, 36.570-900, Viçosa, MG, Brazil INTRODUCTION
Yellow passionfruit (Passilora edulis Sims., Passilo-raceae) is a species typical of tropical climates. It belongs to a group of plants requiring long days, demanding in photoperiod and temperature (Nave et al. 2010). The plant needs a minimum of 11 h light day-1 and monthly average
temperatures around 20 °C, to ensure loral induction and fruit development (Junqueira et al. 1999, Borges and Lima 2009).
In general, the climatic conditions for year-round production of yellow passionfruit are ideal in low-latitude regions near the equator (Cavichioli et al. 2006). Major passionfruit-producing regions are located at latitudes above 15° South. In these regions, the reduction in photoperiod and temperature in the winter adversely affects the passionfruit harvest, which is seasonal.
Mutant plants that can lower when days are short were identiied in the yellow passionfruit breeding program of the Federal University of Viçosa (UFV), Minas Gerais, Brazil. Understanding the genetic control of photoperiod insensi-tivity would facilitate the incorporation of this phenotype in hybrids or cultivars (Bruckner et al. 2005). Genotypes with photoperiod insensitivity to lowering can be used to develop cultivars recommendable for higher-latitude regions, increasing the harvest period.
DEVELOPMENT OF THE MUTANT GENOTYPE
The genotype UFV-M7 was obtained from micro-propagated plants from nodal segments explants exposed to gamma radiation. The plant material, derived from su-perior genotypes identiied by the UFV yellow passionfruit breeding program, was initially irradiated with a view to the establishment of varieties resistant to Fusarium oxysporum f.sp. Passilorae (Flores et al. 2011). The nodal segments in petri dishes containing MS medium were exposed to gamma irradiation (20 Gya) from a 60Co Gammacell source
(0.709 to 0.711 kGy h-1) at the center for nuclear energy
UFV-M7: mutant yellow passionfruit genotype with photoperiod insensitivity for lowering
129 Crop Breeding and Applied Biotechnology 14: 128-131, 2014
day-1, demonstrating insensitivity to short photoperiod for
lowering of this mutant.
CONFIRMATION OF INSENSITIVITY TO SHORT PHOTOPERIOD FOR FLOWERING
To conirm the insensitivity of UFV-M7 to lower under a photoperiod of less than 11 h light.day-1, this genotype was
compared with N9 in an experiment. This plant material is unirradiated and normal in terms of photoperiod require-ment for lowering (over 11 h light day-1). Genotype N9
was derived from a progeny developed by the UFV yellow passionfruit breeding program, based on recurrent selection cycles for fruit yield and quality, with lowering between September and October.
Location
The experiment was carried out in a greenhouse of the Plant Science Department of UFV. The monthly distribution of photoperiod and temperature in the evaluation period is shown in Figure 1. Photoperiod data were obtained by subtracting the hours from sunset to sunrise from 24, by the forecast Center CPTEC/INPE. Temperatures were re-corded by a Datalogger Impact IP-747RH, maintained in a greenhouse with hourly data collection.
Propagation of genotypes
The genotypes UFV-M7 and N9, initially present in the ield, were propagated by cuttings and grown in a greenhouse. The cuttings were collected with three buds, cut between the middle part and the apex of branches of annual growth. After removing the leaves, the cuttings were planted in dibble tubes (6 x 20 cm) containing commercial substrate, at a depth of 4 cm. They were kept under spray irrigation for 5 min, triggered every 1 hour by a timer, from 6 to 18 o’clock.
Test installation and performance
In May/2011, 60 days after planting the cuttings, seed-lings were transplanted to 30 L pots containing a substrate of soil and washed sand (ratio 2:1). Fertilization was applied according to the results of fertility analysis of this substrate. The substrate was maintained near ield capacity by trickle irrigation, using one dripper per pot (microjet spray heads) at a low rate of 14 L/h at 1 kgf cm-2. Thirty-two plants per
genotype were evaluated, with one plant per pot, totaling 64 plants. The seedlings were grown from a single stem (Figure 2A), clipping the lateral branches. When these main stems crossed a wire at a height of 20 cm, they were bent downward, forming a loop. Secondary and tertiary branches
were left to grow from this loop, to assess the lowering period (Figure 2B).
Figure 1. Monthly distribution of photoperiod (N) to the latitude of 20 ° and maximum temperatures (Max. T.), medium (Med. T.) and minimum (Min. T.). Experimental duration (DEA/UFV).
Figure 2. General view of the experiment thirty days (A) and six months (B) after planting; UFV/Viçosa-Minas Gerais, Brazil. Photos: Lira Júnior JS
Figure 3. Flower bud stage to assess beginning of lowering,
130 Crop Breeding and Applied Biotechnology 14: 128-131, 2014 JS Lira Júnior et al.
Evaluation lowering periods
Two evaluation periods were previously established, considering the variations in photoperiod and temperature throughout the year (Figure 1): Period 1 - May 2011 to August 2011, a cold/dry season with short photoperiod, less than 11 h light day-1; Period 2 – September 2011 to December
2012, a warm/humid season with long photoperiod, more than 11 h light day-1.
The evaluated characteristics
The number of lowering plants in the two pre-established periods was evaluated. The beginning of lowering was
Table 1. Morphological traits of two genotypes of yellow passionfruit (Passilora edulis Sims.), contrasting for beginning of lowering at latitude 20° 45´ 14´´ S, propagated by cuttings and grown in a greenhouse
Characteristic Description Genotype UFV(unsensitive) -M7 Genotype N9(normal)
1. Branch: color light green (1); dark green (2); purplish light green(3); purple (4) 3 2
2. Leaf blade: length short< 12cm (3); medium 12-15cm (5); long> 15cm (7) 7 7
3. Leaf blade: greatest width narrow< 12cm (3); medium 12-15cm (5); wide> 15cm (7) 7 7
4. Leaf blade: cavity depth shallow (3); medium (5); deep (7) 7 7
5. Petiole: length short< 3cm (3); medium 3-3.5cm (5); long> 3.5cm (7) 7 7
6. Petiole: nectary position Adjacent to the leaf blade (1); Distant from the leaf blade (2) 1 1
7. Flower: bract length short< 2 cm (3); medium 2-3cm (5); long> 3cm (7) 5 5
8. Flower: sepal length short< 3.5cm (3); medium 3.5-4cm (5); long> 4cm (7) 5 5
9. Flower: sepal width narrow<1.5cm (3); medium 1.5-2cm (5); wide> 2cm (7) 3 3
10. Flower: corona diameter small< 7cm(3); medium 7-8cm(5); large> 8cm(7) 7 5
11. Flower: banding in the corona ilaments absent (1); present (2) 2 2
12. Flower: ring color
(except white) of the corona pink (1); purple (2) 2 2
13. Flower: width of the colored rings in the
corona ilaments narrow<1cm (3); medium 1-1.5cm (5); wide>1.5cm (7) 5 7
14. Flower: corona ilaments straight (1); wavy (2) 1 1
15. Fruit: longitudinal diameter short< 10cm (3); medium 10-13cm (5); long> 13cm (7) 3 3
16. Fruit: transversal diameter small< 8cm (3); medium 8-10cm (5); large> 10cm (7) 3 3
17. Fruit: ratio
Longitudinal diameter/transversal diameter
very small < 0.9 (1); small 0.9-1.2 (3); medium
1.2–1.5 (5); large 1.5-1.8 (7); very large >1.8 (9) 3 3
18. Fruit: shape oval (1); oblong (2); rounded (3); oblata (4); el-lipsoid (5); oboval (6) 3 3
19. Fruit: shell color (epidermis) yellow (1); red (2); purple (3) 1 1
20. Fruit: lenticels inconspicuous (invisible or little visible) (1); conspicuous (visible) (2) 2 2
21. Fruit: mean weight (UFV-M7 x N9 and
N9 x UFV-M7, hand-pollinated)
low< 150g (3); medium 150-250g (5); high>
250g (7) 5 5
22. Fruit: skin thickness thin< 6mm (3); medium 6-10mm(5); thick> 10mm (7) 5 7
23. Fruit: pulp color greenish yellow (1); yellow (2); orange (3); dark orange (4) 3 2
24. Fruit: soluble solids content low< 10ºbrix (3); medium 10º-13ºbrix(5); high> 13ºbrix (7) 5 5
25. Fruit: number of seeds per mature fruit
(UFV-M7xN9 and N9xUFV-M7, with
hand-pollination)
small< 200 (3); medium 200-400 (5); large> 400
(7) 5 5
UFV-M7: mutant yellow passionfruit genotype with photoperiod insensitivity for lowering
131 Crop Breeding and Applied Biotechnology 14: 128-131, 2014
computed when the lower buds in the leaf axil became visible (Figure 3). The evaluation was performed weekly until all plants lowered. Morphological descriptors were also evaluated according to the instructions of the National Plant Variety Protection (SNPC) of the Ministry of Agri-culture, Livestock and Supply (MAPA). The fruit-related characteristics were evaluated based on samples of at least three fruits per plant.
RESPONSE TO VARIATIONS IN PHOTOPERIOD
The genotypes UFV-M7 (mutant) and N9 (unirradiated), propagated by cuttings, began lowering in periods with different photoperiod and temperature (Figures 4A and 4B). The beginning of lowering of UFV-M7 occurred in July 2011, three months after transplanting, at photoperiods of less than 11 h light day-1.and an average air temperature
of around 16 °C (Figure 1), conirmed its insensitivity, in contrast to genotype N9. Genotype N9 initiated lowering between October and November/2011, six months after transplantation, i.e., upon the establishment of the period of higher temperature (average day temperature 20 °C) and favorable photoperiod (over 11 h light day-1) (Junqueira et
al. 1999, Borges and Lima 2009).
MORPHOLOGICAL CHARACTERISTICS Twenty-ive morphological descriptors of two yellow passionfruit (Passilora edulis Sims.) genotypes, contrast-ing in the beginncontrast-ing of lowercontrast-ing, at latitude 20° 45´ 14´´S,
are shown in Table 1. The fruits were obtained by hand-pollinated crosses of UFV - M7 x N9 and N9 x UFV - M7.
PROPAGATIVE PRODUCTION MATERIAL
The Federal University of Viçosa (UFV) is responsible for the maintenance of genotype UFV-M7 and for experiments for the incorporation of this phenotype in yellow passionfruit cultivars or hybrids.
ACKNOWLEDGEMENTS
The authors thank the Brazilian Federal Agency for Support and Evaluation of Graduate Education (CAPES), the National Council for Scientiic and Technological De-velopment (CNPq) and Research Foundation of the state of Minas Gerais (FAPEMIG) for inancial support, and the Centre for Nuclear Energy in Agriculture (CENA/USP) for providing irradiation facilities.
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Figure 4. Number of plants observed at the beginning of lowering of the
